The present disclosure relates to downhole tools, and more particularly to tools for reduction of inoperability and/or damage of electrical submersible pumps due to solid particle (e.g., formation sand, proppant, and the like) fall back such as used in oil and gas wells.
Natural formation sands and/or hydraulic fracturing proppant (referred to herein as sand) in subterranean oil and gas wells can cause significant problems for electrical submersible pumps (ESPs). Once sand is produced through the ESP it must pass through the tubing string prior to reaching the surface. Sand particles often hover or resist further downstream movement in the fluid stream above the ESP or move at a much slower velocity than the well fluid due to physical and hydrodynamic effects. When the ESP is unpowered, fluid and anything else in the tubing string above the pump begins to flow back through the pump. Check valves are often used to prevent flow back while also maintaining a static fluid column in the production tubing. However check valves are subject to failures caused by solids including sand.
Such conventional methods and systems have generally been considered satisfactory for their intended purpose. However, there is still a need in the art for improved sand fall-back prevention/mitigation tools that protect the operability and reliability of ESPs. The present disclosure provides a solution for this need.
So that those skilled in the art to which the subject disclosure appertains will readily understand how to make and use the devices and methods of the subject disclosure without undue experimentation, preferred embodiments thereof will be described in detail herein below with reference to certain figures, wherein:
Reference will now be made to the drawings wherein like reference numerals identify similar structural features or aspects of the subject disclosure. For purposes of explanation and illustration, and not limitation, a partial view of an exemplary embodiment of a downhole tool in accordance with the disclosure is shown in
String 10 includes production tubing 12, downhole tool 100, ESP 14, protector 16, and motor for driving ESP 14. These components are strung together in a formation for production, e.g., of oil, gas and/or water, from within formation 20. In
With reference now to
A poppet valve 110 is mounted within the housing. The poppet valve 110 includes an upper member 112 defining an upper chamber 114 mounted in the flow path 104 so that flow through the flow path 104 flows around the upper member 112. A valve seat 116 is mounted in the flow path 104 with an opening 118 therethrough. A valve poppet 120 is mounted for longitudinal movement, e.g., in the direction of axis A, within the flow path 104 between a closed position, shown in
In both the open and closed positions, as shown in
The upper member 112 includes an upper surface 124 with at least one angled portion 126 that is angled, e.g. at angle α below the level dashed line in
As shown in
With reference again to
Housing 102 also includes a base 144 including the lower opening 108 and the valve seat 116. Housing 102 further includes a housing body 146 mounted to the head 142 and base 144, spacing the head 142 and base 144 apart axially. Flow path 104 includes upper opening 106, passages 148 through head 142, the space 149 between housing body 146 and poppet valve 110 (as shown in
A method of reducing fall-back sand reaching an electrical submersible pump (ESP) includes holding a valve poppet, e.g., valve poppet 120, in an open position by operating an ESP, e.g., ESP 14, to drive flow through a flow path, e.g. flow path 114, past the valve poppet, as shown in
Referring now to
Accordingly, as set forth above, the embodiments disclosed herein may be implemented in a number of ways. For example, in general, in one aspect, the disclosed embodiments relate to a downhole tool for sand fall-back prevention. The downhole tool comprises, among other things, a housing defining a flow path therethrough in an axial direction from an upper opening to a lower opening. A poppet valve is mounted within the housing. The poppet valve includes an upper member defining an upper chamber mounted in the flow path so that flow through the flow path flows around the upper member, and a valve seat mounted in the flow path with an opening therethrough. A valve poppet is mounted for longitudinal movement within the flow path between a closed position in which the valve poppet seats against the valve seat to block flow through the flow path and an open position in which the valve poppet is spaced apart from the valve seat to permit flow through the flow path.
In general, in another aspect, the disclosed embodiments related to a method of reducing fall-back sand reaching an electrical submersible pump (ESP). The method comprises, among other things, holding a valve poppet in an open position by operating an ESP to drive flow through a flow path past the valve poppet, moving the valve poppet into a closed position blocking the flow path by reducing flow from the ESP, blocking sand through the flow path with the valve poppet, and preventing accumulation of sand above, e.g., directly above, the valve poppet while the valve poppet is in the closed position.
Referring additionally to
In certain embodiments, the one or more angled passageways 919a, 919b can include one or more linear passageways defined between a respective radially inward opening 923a, 923b and radially outward opening 925a, 925b. In certain embodiments, as shown, the passageways 919a, 919b can have a uniform cross-sectional flow area between the radially inward opening 923a, 923b and radially outward opening 925a, 925b. It is contemplated that non-uniform cross-sectional areas (e.g., reducing or expanding, tapered) can be utilized. The angled passageways 919a, 919b can be and/or include any other suitable flow path (e.g., non-linear, having concave or convex curved features as part of or making the entire length of the upward flow path, having end connected linear segments creating a progressing or digressing upward flow angle) within the wall 921 of the sand bridge inducer 916 between the radially inward opening 923a, 923b and the radially outward opening 925a, 925b.
In certain embodiments, the one or more angled passageways 919a, 919b can include one or more plate flow passageways including a rectangular cross-section (e.g., as shown in
In certain embodiments, as shown, the gap dimension “g” can be vertical or aligned to the axial direction/axial flow path (e.g., as shown in
The at least one of the angled passageways 919a, 919b can include an angle γI of 45 degrees or higher between the radially inward opening 923a, 923b and radially outward opening 925a, 925b. Any other suitable angle is contemplated herein.
The angled passageways 919a, 919b can be cut at a severe angle γI for at least two reasons. First, an aggressive angle, e.g., greater than the angle of repose for the material such as sand that is desired to be blocked from back flow, can hinder sand from flowing upward through the passageways 919a, 919b. Second, the angled orientation allows for a longer passageway 919a in the depth dimension “d” (e.g., as shown in
At least one of the one or more angled passageways 919a, 919b can be sized to promote a sand bridging effect therein without allowing sand to travel into the main opening 917. The one or more angled passageways 919a, 919b can include at least two passageways of different flow area. For example, as shown in
In certain embodiments, the first passageway 919a includes a gap “A” and a flow area that is smaller than the second passageway 919b. The smaller gap of the first passageway 919a can be sized to not require leak-off to induce a sand bridge in the first passageway 919a path, whereas the larger gap of the second passageways 919b can require higher sand concentrations to have an effective sand bridge.
In certain embodiments, the smaller first passageway 919a can be sized to allow leak-off during downflow, e.g., such that mostly or only liquid will be removed from the slurry flow by way of the first passageway 919a. Path 919a leaks off fluid upstream of 919b thereby causing a higher concentration of sand particles present at the opening of 919b. The higher concentration of sand particles promotes sand bridging in 919b, e.g., when 919b has been configured with a gap dimension larger than 919a. The larger second passageway 919b can be designed to allow sand bridging therein such that sand (and/or other sediment or solid particulate) can collect in the second passageway 919b without being able to flow into the main opening 917.
The sand bridge inducer 916 can include a top hat shape or any other suitable shape. For example, as shown, the sand bridge inducer 916 can include a mounting flange 931, e.g., for mounting in a tool housing such that flow must flow through the main opening (e.g., via the angled passageways 919a, 919b). In certain embodiments, the sand bridge inducer 916 can include an interface 933 at a top (axially upward) portion thereof, e.g., for acting as a valve seat for sealing interaction between a poppet and the sand bridge inducer 916. In certain embodiments, it is contemplated that the top portion of the sand bridge inducer 916 can be sealed in any suitable manner.
If the main opening 917 is sealed at the top (e.g., from a cap, from design, from a poppet blocking the main opening 917), flow will have to pass through the angled passageways 919a, 919b to flow into the main opening 917. In this regard, the upward angled passageways 919a, 919b are sized, shaped, angled, and/or otherwise designed to allow liquid to travel through the one or more angled passageways 919a, 919b without allowing sand and/or other sediment/solid particulate from entering the main opening 917. In upward flow, sand is allowed to go through the passageways 919a, 919b, e.g. when upward flow sand concentrations are less than 0.1% by volume, or through 917 if the poppet 920 opens. The poppet will open when plugging occurs, e.g. when sand slugs having a high concentration of sand in the tubing flow occurs during upward flow, or high flow rates are encountered.
Embodiments, of sand bridge inducer 916 can be utilized in a valve assembly, e.g., as a valve seat for example. Referring to
As shown in
In certain embodiments, as shown, the poppet valve 910 includes a poppet 920 that may be solid and/or does not include any flow passage therethrough, for example. Any other suitable poppet (e.g. having other shapes being solid and/or having flow passages) or assembly is contemplated herein.
The sand bridge inducer 916 can be used in any suitable manner within any suitable well system and/or well tool (e.g., used as a valve seat 916 as shown in
Referring to
Referring to
As described above, the angled passageways 919a, 919b can have small gaps (e.g., high aspect ratios) that are wide thereby allowing for an overall large flow area. The small gap size is sized to promote a sand bridging effect when sand concentrations rise. When sand bridges form in/at all the narrow gap passageways (e.g., passageways 919a and/or 919b), this effectively impedes sand fall-back.
As described above, embodiments include a valve that includes an upper poppet and a sand bridge inducer. In such embodiments, the poppet does not need to have internal flow paths. Embodiments use the poppet to ensure upward flow by opening when the sand bridge inducer 916 becomes plugged due to sand slug events or short periods of thick debris that has been produced through the ESP pump. When the poppet opens during normal upward flow, any solids or debris attempting to plug the sand bridge inducer at radially inward opening 923a and/or 923b can be flushed through the tool thereby allowing the tool to return to normal operation.
Embodiments as described above can include narrow yet wide passageways that are cut at aggressive angles into the sand bridge inducer 916. These passageways hydraulically can connect the lower part of the valve with the upper part of the valve. Embodiments can effectively create “plate-flow” (flow between two flat plates) which can promote sand bridging. Yet, because embodiments can also include a wide (horizontal) dimension the overall flow area is enlarged. The increased flow area can aid in reducing localized flow velocities and overall pressure drop across the tool. Reduced flow velocity can also promote sand bridging during downward flow (fall-back) while also reducing erosion during normal upward flow.
Also as described above, certain embodiments include upper passageways that have the narrowest gap while the lowest passageways have the largest gap. When a fall-back event occurs, sand particle and fluid will first reach the small gap passageways. In such embodiments where these passageways are smaller, sand particles are less encouraged to enter the passageway and therefore continue flowing downward toward the large gap passageways. Meanwhile, fluid particles easily flow through the small gap passageways (e.g. 919a) thereby causing a “leak-off” effect. Fluid effectively “leaks” from the slurry which can increase the slurry's sand concentration just below the small gap passageways, and prior to the large gap passageway (e.g. 919b).
Certain embodiments can have small gap lower passageways that are designed to easily form a sand bridge when sand concentrations are lower, and thus do not require leak-off support. Gap size selection of the angled passageways can be related to the targeted sand particle size. For example, the gap dimension can be designed from one to three times the diameter of the target particle size in certain embodiments. Since leak-off causes an increased sand concentration that promotes sand bridging in the lower yet larger gap passageways, such passageways may be designed anywhere from three to six times the diameter of the target particle size. As sand concentration ranges increase, the gap size may also be increased because an increasing sand concentration also promotes sand bridging.
As described above, utilizing plate-flow geometry with graduated gap sizes allows for an overall effective and efficient means of flow-back while quickly inducing a sand bridge if sand particles are present. If no sand was present, embodiments would cause little flow restriction resulting in a flow-back rate nearly equal to a system not having the tool installed. This can be because of the flow area achieved by cumulating all the angled passageways. The number of angled passageways (and overall tool length) can be minimized using graduated gap sizing.
After a sand bridge has been formed during a fall-back event, the tool then causes fall-back sand to remain in the production tubing above the tool instead of flowing back into/onto the ESP pump. When the ESP pump has been successfully restarted the fluid below the tool is pressurized. This pressure is instantly communicated through the plate-like passageways and to the sand column in and above the tool. Once this occurs, the buoyancy of the sand changes and the sand column begins to re-fluidize. Once the sand column has been re-fluidized sand particles will begin to flow upward toward the surface. After flow has been established the sand that was once bridged in the tool will flow out (and upward) from the tool. If clogging occurs in the sand inducer element passageways at openings 923a/923b the poppet will open due to the differential pressure established by the pressure just below the poppet seat and the pressure in the upper chamber just above the poppet. When the poppet opens, debris/sand in 917 will clear through the tool and fluidization of the sand column above the tool will be improved and therefore promoting sand production upward and away from the tool.
In accordance with any of the foregoing embodiments, in both the open and closed positions, the valve poppet can be at least partially within the upper chamber so that the upper chamber is always enclosed to prevent accumulation of fall-back sand above the valve poppet. In accordance with any of the foregoing embodiments, a biasing member can be seated in the upper chamber biasing the valve poppet toward the valve seat.
In accordance with any of the foregoing embodiments, the upper member can include an upper surface with at least one angled portion that is angled to resist accumulation of sand on the upper surface.
In accordance with any of the foregoing embodiments, the valve poppet can be narrower than the upper chamber to allow movement of the valve poppet without resistance from fall-back sand or debris.
In accordance with any of the foregoing embodiments, the valve poppet can include an axially oriented perimeter surface matched in shape with an axially oriented interior surface of the upper chamber.
In accordance with any of the foregoing embodiments, a wiper seal or similar functioning seal can engage between the valve poppet and the upper member, wherein the seal is configured to allow passage of fluid while inhibiting passage of sand or debris.
In accordance with any of the foregoing embodiments, a weep hole can be defined through the upper member from a space outside the upper chamber to a space inside the upper chamber, wherein the weep hole is configured to equalize pressure between the space outside the upper chamber with the space inside the upper chamber. A filter material can be included within the weep hole.
In accordance with any of the foregoing embodiments, the valve seat can be defined by an angular surface configured to encourage wedging of sand during closing of the valve poppet against the valve seat.
In accordance with any of the foregoing embodiments, a poppet channel can be defined through the valve poppet for limited fluid communication through the flow path with the valve poppet in the closed position. The poppet channel can have a flow area equal to one-half of that through the flow path or greater. The poppet channel can include a tributary with an opening on a peripheral surface of the poppet valve, wherein the tributary of the poppet channel is directed downward toward the valve seat for initiating a buoyancy change in sand seated between the valve seat and the valve poppet prior to the valve poppet moving from the closed position to the open position. The tributary of the poppet channel can be defined along a tributary axis angled downward, e.g., 45° from level.
In accordance with any of the foregoing embodiments, the housing can include a head including the upper member and upper opening, a base including the lower opening and the valve seat, and a housing body mounted to the head and base, spacing the head and base apart axially.
In accordance with any of the foregoing embodiments, back flow can be allowed through a poppet channel defined through the valve poppet.
In accordance with any of the foregoing embodiments, initiating movement of the valve poppet from the closed position to an open position can be done by directing flow through a tributary of a poppet channel defined through the valve poppet, wherein the flow through the tributary is directed at sand accumulated between the valve poppet and an adjacent valve seat.
In accordance with any of the foregoing embodiments, increasing flow through the ESP can move the valve poppet into an open position for flow through the flow path, and accumulated fall-back sand can be discharged from a tool including the valve poppet in an upward direction.
In accordance with any of the foregoing embodiments, a downhole tool for sand fall-back prevention can include a housing defining a flow path therethrough in an axial direction from an upper opening to a lower opening, and a poppet valve mounted within the housing, wherein the poppet valve includes an upper member defining an upper chamber mounted in the flow path so that flow through the flow path flows around the upper member, a sand bridge inducer valve seat mounted in the flow path with a main opening therethrough, wherein the sand bridge inducer valve seat includes one or more angled passageways defined through a wall of the sand bridge inducer valve seat such that the one or more angled passageways open from a radially inward opening and traverse axially downward through the wall of the sand bridge inducer valve seat toward a radially outward opening, and a valve poppet mounted for longitudinal movement within the flow path between a closed position in which the valve poppet seats against the sand bridge inducer valve seat to block flow through the flow path and an open position in which the valve poppet is spaced apart from the valve seat to permit flow through the flow path.
In accordance with any of the foregoing embodiments, the one or more angled passageways can include one or more linear or curved passageways defined between a respective radially inward opening and radially outward opening.
In accordance with any of the foregoing embodiments, the one or more angled passageways can include one or more plate flow passageways including a rectangular cross-section.
In accordance with any of the foregoing embodiments, a cross-sectional area of the one or more plate flow passageways include a 10:1 width to gap ratio, and wherein the plate flow passageways include a depth to gap ratio of 20:1.
In accordance with any of the foregoing embodiments, at least one of the one or more angled passageways can be sized to promote a sand bridging effect therein without allowing sand to travel into the main opening.
In accordance with any of the foregoing embodiments, the one or more angled passageways can include at least two passageways of different flow area.
In accordance with any of the foregoing embodiments, a first passageway of the at least two passageways can have a smaller flow area than a second passageway, wherein the first passageway is disposed axially upward of the second passageway.
In accordance with any of the foregoing embodiments, the smaller first passageway can be sized to allow leak-off from downflow and the larger second passageways can be designed to allow sand bridging therein.
In accordance with any of the foregoing embodiments, the at least one of the angled passageways can include an angle of 45 degrees.
In accordance with any of the foregoing embodiments, the sand bridge inducer valve seat can include a top hat shape with a flow opening in a top thereof and a mounting flange axially opposed to the top, wherein an interface between the poppet and the sand bridge inducer valve seat can be at a top of the top hat shape.
In accordance with any of the foregoing embodiments, a sand bridge inducer for a downhole tool includes a wall defining a main opening therethrough and one or more angled passageways defined through the wall such that the one or more angled passageways open from a radially inward opening and traverse axially downward through the wall toward a radially outward opening.
In accordance with any of the foregoing embodiments, the one or more angled passageways can include one or more linear or curved passageways defined between a respective radially inward opening and radially outward opening.
In accordance with any of the foregoing embodiments, the one or more angled passageways can include one or more plate flow passageways including a rectangular cross-section.
In accordance with any of the foregoing embodiments, a cross-sectional area of the one or more plate flow passageways include a 10:1 width to gap ratio, and wherein the plate flow passageways include a depth to gap ratio of 20:1.
In accordance with any of the foregoing embodiments, at least one of the one or more angled passageways can be sized to promote a sand bridging effect therein without allowing sand to travel into the main opening.
In accordance with any of the foregoing embodiments, the one or more angled passageways can include at least two passageways of different flow area.
In accordance with any of the foregoing embodiments, a first passageway of the at least two passageways can have a smaller flow area than a second passageway, wherein the first passageway is disposed axially upward of the second passageway.
In accordance with any of the foregoing embodiments, the smaller first passageway can be sized to allow leak-off from downflow and the larger second passageways can be designed to allow sand bridging therein.
In accordance with any of the foregoing embodiments, the at least one of the angled passageways can include an angle of 45 degrees.
In accordance with any of the foregoing embodiments, the sand bridge inducer valve seat can include a top hat shape with a flow opening in a top thereof and a mounting flange axially opposed to the top, wherein an interface between the poppet and the sand bridge inducer valve seat can be at a top of the top hat shape.
The methods and systems of the present disclosure, as described above and shown in the drawings, provide for reduction or prevention of fall-back sand reaching an ESP with superior properties including accommodation for desirable back flow, extended useable life, and improved reliability relative to traditional systems and methods. While the apparatus and methods of the subject disclosure have been shown and described with reference to preferred embodiments, those skilled in the art will readily appreciate that changes and/or modifications may be made thereto without departing from the scope of the subject disclosure.
This application is the national phase under 35 U.S.C. § 371 of International Application No. PCT/US2017/012025, filed Jan. 3, 2017, which is a Continuation-in-Part of International Application No. PCT/2016/051461, filed Sep. 13, 2016. The entire content of each is incorporated by reference herein.
Filing Document | Filing Date | Country | Kind |
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PCT/US2017/012025 | 1/3/2017 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2018/052470 | 3/22/2018 | WO | A |
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“SandRight Solids Fallback Preventer: Sand Management Tool”; Summit ESP, A Halliburton Service; 2019; 2 pages. |
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Number | Date | Country | |
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20190271210 A1 | Sep 2019 | US |
Number | Date | Country | |
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Parent | PCT/US2016/051461 | Sep 2016 | US |
Child | 16325363 | US |